Simulation of Autonomous Driving for a Line-Following Robotic Vehicle: Determining the Optimal Manoeuvring Mode

IF 0.9 4区 工程技术 Q4 ENGINEERING, ELECTRICAL & ELECTRONIC
Murat Bakirci
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Abstract

Mobile robotic systems offer valuable test platforms due to their shared features with autonomous vehicles, including features such as sensor technologies, navigation algorithms, and control systems. However, constraints in laboratory environments or technical resources, along with the need for extensive testing, often necessitate the use of virtual test laboratories. While line-following is a widely preferred application in mobile robotics, research on this topic within virtual laboratories is limited. This study pioneers the use of a car-like robotic vehicle in conducting line-following tests within a virtual laboratory environment. To facilitate these tests, a virtual simulator was developed to meet the requirements of realistic simulations. This simulator includes simulated elements, such as roads and environmental features, along with virtual sensors designed to collect and process dynamic motion data. An exceptional aspect of this study is its ability to collect consistent dynamic travel data by sampling realistic sensor information within a virtual environment. The developed line-following algorithm employs a controller to minimise lateral deviation while the robotic vehicle follows a road line during its movement. The study conducted virtual driving tests using two different manoeuvre modes on four distinct road segments, exploring how the manoeuvring style influences the driving quality. It was demonstrated that in the low manoeuvre mode, the ride is more comfortable, but exhibits a greater route deviation due to reduced oscillation, while the high manoeuvre mode exhibits the opposite behaviour.
线路跟踪机器人车辆的自主驾驶模拟:确定最佳操纵模式
移动机器人系统具有与自动驾驶汽车相同的特点,包括传感器技术、导航算法和控制系统等,因此可提供宝贵的测试平台。然而,由于实验室环境或技术资源的限制,加上需要进行大量测试,因此往往需要使用虚拟测试实验室。虽然直线跟踪是移动机器人技术中广受青睐的应用,但在虚拟实验室中对这一主题的研究却十分有限。本研究开创性地在虚拟实验室环境中使用类似汽车的机器人车辆进行线路跟踪测试。为了方便这些测试,我们开发了一个虚拟模拟器,以满足真实模拟的要求。该模拟器包括道路和环境特征等模拟元素,以及用于收集和处理动态运动数据的虚拟传感器。这项研究的一个特别之处在于,它能够通过在虚拟环境中采样真实的传感器信息来收集一致的动态行驶数据。所开发的线路跟踪算法采用了一种控制器,在机器人车辆移动过程中跟踪道路线路时,将横向偏差降到最低。研究使用两种不同的操纵模式在四个不同的路段进行了虚拟驾驶测试,探索操纵方式如何影响驾驶质量。结果表明,在低机动模式下,驾驶更加舒适,但由于振荡减小,路线偏离较大,而高机动模式则表现相反。
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来源期刊
Elektronika Ir Elektrotechnika
Elektronika Ir Elektrotechnika 工程技术-工程:电子与电气
CiteScore
2.40
自引率
7.70%
发文量
44
审稿时长
24 months
期刊介绍: The journal aims to attract original research papers on featuring practical developments in the field of electronics and electrical engineering. The journal seeks to publish research progress in the field of electronics and electrical engineering with an emphasis on the applied rather than the theoretical in as much detail as possible. The journal publishes regular papers dealing with the following areas, but not limited to: Electronics; Electronic Measurements; Signal Technology; Microelectronics; High Frequency Technology, Microwaves. Electrical Engineering; Renewable Energy; Automation, Robotics; Telecommunications Engineering.
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